Reconfigurable Photonic Metamaterials

Reconfigurable photonic metamaterials enable dynamic optical nanocavities with tunable light–matter interactions, controllable nonlinearity, quantum interconnects, and tailored lattice–defect coupling. These advances open new possibilities for nonlinear optics, quantum information, and adaptive photonic technologies.

Research in reconfigurable photonic metamaterials focuses on designing and realizing dynamic optical nanocavities with tunable properties, enabling precise control over light–matter interactions at the nanoscale. By engineering controllable nonlinear optical responses and quantum interconnects, these metamaterials open pathways for arbitrary control of photon properties. The platform also allows exploration of tailored lattice–defect interactions, providing new opportunities to study and harness defect-mediated phenomena. Together, these advances pave the way for next-generation technologies in nonlinear optics, quantum information, and adaptive photonics.

Published Works

Twisted Bilayer Photonic Crystals

A Van der Waals Moiré Bilayer Photonic Crystal Cavity

An adaptive moiré sensor for spectro-polarimetric hyperimaging

Control of Chirality and Directionality of Nonlinear Metasurface Light Source via Moiré Engineering

Free-Space Beam Steering with Twisted Bilayer Photonic Crystal Slabs

Three-Dimensional Reconfigurable Optical Singularities in Bilayer Photonic Crystals

GaN Magic Angle Laser in a Merged Moiré Photonic Crystal

Experimental probe of twist angle–dependent band structure of on-chip optical bilayer photonic crystal

On-chip light trapping in bilayer moiré photonic crystal slabs

Modeling the optical properties of twisted bilayer photonic crystals

Photonic Crystals:

Low-Loss Zero-Index Materials

Ultra-low-loss on-chip zero-index materials

Photonic flatband resonances for free-electron radiation

Extended many-body superradiance in diamond epsilon near-zero metamaterials